KR20130120145A - High density damper - Google Patents

Abstract

The present invention provides a vibration control damper having high density, capable of reducing vibration energy with a plurality of concentrated damping elements by being arranged in the circumference direction and enlarging vibration control width. According to embodiment of the present invention, the vibration control damper includes a pair of first and second link support bodies facing each other; the plural pairs of first links and second links arranged in the circumference direction at a regular interval as one end is hinged by being overlapped, and the other end is individually hinged to the first link support body and the second link support body; a clamping bolt generating surface pressure in the damping element by being individually installed in the hinged part in which the first link and the second link are connected; and the damping element arranged in between the first link and the second link by being inserted into the clamping bolt.

Description

 High Density Damper

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a damping damper, and more particularly, to a highly integrated damping damper having a damping element arranged in the circumferential direction and dissipating vibration energy and increasing the damping width.

The damping device uses a steel damper manufactured to dissipate energy using the yield mechanism of the steel, a friction damper using a friction mechanism as an energy dissipation device, and a viscous material showing velocity dependence. Viscous dampers that dissipate, and viscoelastic dampers that dissipate energy input into the system using viscoelastic materials that exhibit both velocity and displacement dependence. With these steel dampers, friction dampers, and viscous dampers as the starting point, the vibration suppression device has been widely recognized by seismic and structural engineering systems as a way to improve the seismic performance of structures in recent 20 years. This is an increasing trend.

However, despite the studies on the excellent seismic performance of vibration damping devices using vibration damping devices and various practical applications, the use of vibration damping devices is extremely limited in Korea. Recently, however, as concerns about indirect damage from earthquakes in Japan have spread and uncertainties about earthquake damage areas have increased, attempts have been actively made to research and apply domestic vibration damping devices.

However, steel dampers have the disadvantage of replacing the dampers due to residual deformation due to plastic deformation. In the case of friction dampers, frictional force is also important, but wear of friction materials and the expansion of the base material due to frictional heat are increased. There is a disadvantage that frictional uncertainty due to cold welding, which can occur when the frictional force does not occur in the state where the strength decreases due to various complex friction phenomenon and the vertical pressure is applied, is disadvantageous. In addition, steel dampers and friction dampers do not match the wind-proof design concept for the elastic design because residual deformation occurs after operation has the additional disadvantage that can not be used for vibration control by wind. Viscous dampers are disadvantageous in that they are more expensive than steel dampers or friction dampers as well as continuous maintenance.

In order to minimize the economic damage caused by earthquakes due to the rapid urbanization, population concentration, and high rise of buildings in the design of earthquakes, it is an international trend to examine the statistical safety rate for the maximum earthquake greater than the design earthquake. . Considering the economics, it is difficult to simultaneously control the vibration of the structure caused by wind and earthquake by installing the above-mentioned individual dampers on the structure, and it is more difficult to secure a proper safety rate against the international maximum level earthquake.

As a background technology of the present invention, Korean Patent Registration No. 10-0977041 refers to the 'dust removal hunt for building'. It is a vibration damping haunch of a building installed in a beam-column junction or a wall-floor junction of a building, the horizontal plate being fixed to a beam or a bottom plate; A vertical plate fixed to a column or wall; A vibration damping unit having one side hinged to the horizontal plate and the vertical plate to absorb vibration, and having at least one lead core; A first link having one end hinged to the horizontal plate via a hinge portion and the other end coupled to the other side of the vibration suppression unit; One end is hinged to the vertical plate via the hinge portion and the other end is coupled to the other side of the vibration suppression unit, so that the energy (earthquake force, etc.) input to the building by the plurality of links and the vibration suppression unit is efficiently By absorbing, it is possible to prevent deformation of the building as much as possible.

However, the background art has a disadvantage that it is difficult to dissipate large deformation energy of the structure because of the small damping width.

Korean Patent Registration No. 10-1070259 Korea Patent Registration No. 10-0982240

SUMMARY OF THE INVENTION An object of the present invention is to provide a toggle type highly integrated damping damper which has a damping element arranged in a circumferential direction and dissipates vibration energy and increases a damping amplitude.

According to a preferred embodiment of the present invention,

A pair of first and second link supporting bodies facing each other;

A plurality of pairs of first links and second links, one end of which is hinged to each other and the other ends of which are hinged to the first link support body and the second link support body, and are arranged at regular intervals in the circumferential direction;

Tightening bolts respectively installed at hinge portions at which the first link and the second link are connected to generate surface pressure on a damping element; And

And a damping element inserted into the tightening bolt and disposed between the first link and the second link.

In addition, the first link support body and the first end connector; A first spacing member having a crisscross shape and connected to the first end connector; Characterized in that it consists of a plurality of link connecting members having an L-shaped cross-section, respectively mounted on a right angled surface of the cross-shaped cross section of the first spacing member.

In addition, the second link support body and the second end connector; And a second spacing member connected to the second end connector having a crisscross shape.

In addition, the damping element is characterized in that the plate-shaped high damping rubber.

In addition, the damping element is an aluminum composite material in which ceramic particles are dispersed and reinforced in aluminum or an aluminum alloy, a carbon-carbon composite material, a semi-metallic friction material using metal fibers, a furnace steel type using a mixture of metal fibers and organic / inorganic fibers. It is characterized by consisting of a friction pad made of any one of a non-steel friction material using only organic and non-machined fibers without using any friction material, metal fiber.

In addition, the damping element is characterized in that the friction pad protrudes on the surface of the disc is arranged in a plurality in the circumferential direction.

According to the toggle type high damping damper according to the present invention, the damping element is arranged in the circumferential direction through the hinge portion between the links, and the damping element is concentrated in a plurality, so that the vibration damping performance is improved, and the linear motion is rotated to the damping element. The vibration damping width can be increased by converting the resin into an elastic material and causing elastic deformation or friction.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a perspective view of a toggle type highly integrated vibration damper according to the present invention.
2 is a sectional view taken along the line AA in Fig.
Figure 3 is a front view of a toggle high-density vibration damper according to the present invention.
Figure 4a is a plan view showing an example of a friction pad applied to the present invention.
4B is a cross-sectional view taken along the line BB of FIG. 4A.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

1 to 3, the damping damper 10 according to the present embodiment includes a pair of first and second link supporting bodies 20 and 30 facing each other. The first and second link supporting bodies 20 and 30 are disposed to face each other in a straight line X at regular intervals.

The first link support body 20 has a first end connector 21, a first cross member 22 having a cross-shaped cross-section 221 and connected to the first end connector 21, and a first interval member ( It consists of a plurality of link connecting members (23) having an L-shaped cross-section, respectively mounted on a right angled surface of the cross-shaped cross-section 221 of (22).

The first end connector 21 is constituted by a pair of plates having a connection hole 21a. The first end connector 21 is connected to the first spacing member 22 through the fastening of the bolt B1 and the nut N1. In the present invention, the first end connector 21 is not limited to such a plate-like structure. The thickness of the cross-shaped cross-section 221 in the first interval member 22 may be configured to be equal to or slightly larger than the thickness of the first link 40 to be described later. The link connecting member 23 may be made of L-shaped steel because it has an L-shaped cross section. At this time, one end of the link connecting member 23 is connected to the first spacing member 22 through a plurality of bolts B2 and nuts N2.

The second link support body 30 includes a second end member 32 having a second end connector 31 and a cross-shaped cross section 321 and connected to the second end connector 31. The second end connector 31 is constituted by a pair of plates having a connection hole 31a. The second end connector 31 is connected to the second spacing member 32 through the fastening of the bolt B3 and the nut N3. In the present invention, the second end connector 31 is not limited to such a plate-like structure.

Between the first link support body 20 and the second link support body 30, a plurality of pairs of the first link and the second link 40, 50 are arranged at regular intervals in the circumferential direction. The first link 40 and the second link 50 of each pair are hinged through the fastening bolt 60, respectively, one end thereof overlaps. At this time, the other end of the first link 40 is connected to the first link connecting member 23 and the other end of the second link 50 is hinged to the second spacing member 32 through bolts and nuts, respectively. At this time, each pair of the first link 40 and the second link 50 has a variable angle θ that is uniformly opened inward. This variable angle is initially set smaller than 180 degrees and larger than 45 degrees. In the present embodiment, the second link 50 is configured as a pair, but may also be configured as one body.

Tightening bolt 60 is respectively installed in the hinge portion where the first link 40 and the second link 50 is connected to adjust the surface pressure applied to the damping element 70 by the fastening force with the nut 62. .

The damping element 70 is inserted into the tightening bolt 60. In this embodiment, the damping element 70 is disposed between the first link 40 and the second link 50. In the present embodiment, the second link 50 is configured as a pair, and two damping elements 70 are installed in one fastening bolt 60. Therefore, in the present embodiment, the first link 40 and the second link 50 are installed at all four places at intervals of 90 degrees in the circumferential direction, and thus all eight damping elements 70 are installed.

The damping element 70 may be, for example, a plate-shaped high damping rubber having high elastic stiffness and large energy dissipation capacity. The high damping rubber may be manufactured separately and installed or may be installed by injection in a mold. The damping element 70 may be constituted by a friction pad of a plate type as another example. Friction pads are made of aluminum composites, carbon-carbon composites, semi-metallic friction materials using metal fibers, metal fibers and organic / inorganic fibers. It can be made of any one of a low-steel friction material using a mixed material, a non-steel friction material using only organic and inorganic fibers without using any metal fibers. 4A and 4B, the damping element 70 may be formed by arranging a plurality of friction pads 72 on the surface of the disk 71 in the circumferential direction.

The operation of the damping damper configured as described above will be described.

First, the damping damper 10 decreases or increases the variable angle θ of the first link 40 and the second link 50 according to the direction of the load acting on the first and second end connectors 21 and 31. To perform the damping.

That is, when the compressive load acts on the first and second end connectors 21 and 31 in the direction of arrow C, as shown in FIG. In this process, when looking at one damping element 70, the shearing forces acting in different directions from each other. As a result, the variable angle θ of the first link 40 and the second link 50 becomes small. Therefore, when the damping element 70 is made of high damping rubber, elastic deformation occurs and the vibration energy is absorbed by the resistance of the shear deformation generated in this process.

In addition, when a tensile load is applied to the first and second end connectors 21 and 31 in the direction of arrow T, the first link support body 20 and the second link support body 30 move in a direction far from each other. Looking at one damping element (70) in the shear force different in direction to each other will act the same. As a result, the variable angle θ of the first link 40 and the second link 50 is increased. Therefore, when the damping element 70 is made of high damping rubber, elastic deformation occurs and the vibration energy is absorbed by the resistance of the shear deformation generated in this process.

In this case, when the damping element 70 is a friction pad regardless of the direction acting on the first and second end connectors 21 and 31, the seismic load is dissipated by the friction energy.

The damping damper 10 acting as described above has a damping element 70 which is arranged in a circumferential direction and concentrated in a plurality, so that the energy dissipation capacity is increased. In addition, the damping width can be increased by using the variable angles of the first link 40 and the second link 50.

Therefore, the damping damper 10 is installed through the brace 100 on the beam 1 and the pillar 2 as shown in FIG. 5, for example, to amplify the displacement similarly to the toggle damper to perform the damping.

On the other hand, the present invention is configured to arrange the first link 40 and the second link 50 every 90 intervals, but by changing the shape, structure and size of the first and second link support body (20,30) It may be installed with an interval of less than that angle. The second link 50 may be formed on the side of the first link supporting body 20 and the first link 40 on the second link supporting body 30 side.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

20: first link support body
21: first end connector
22: first spacing member
23: Link link member
30: second link support body
31: second end connector
32: second spacing member
40: first link
50: second link
60: Tightening bolt
70: damping element

Claims (6)

A pair of first and second link supporting bodies 20 and 30 facing each other;
A plurality of pairs of first links and a plurality of second links, each of which is hinge-connected and hinged to each other and hinged to the first link supporting body (20) and the second link supporting body (30) 2 links (40, 50);
Tightening bolts 60 are respectively installed in the hinge portion to which the first link 40 and the second link 50 is connected to cause a surface pressure on the damping element 70; And
Toggle high-density vibration damper, characterized in that the damping element 70 is inserted into the tightening bolt (60) disposed between the first link (40) and the second link (50). The method of claim 1,
The first link support body 20
A first end connector 21;
A first interval member 22 having a cross-shaped cross section and connected to the first end connector 21;
Toggle highly integrated damping damper, characterized in that consisting of a plurality of link connecting members having an L-shaped cross-section, each mounted on a right angled surface of the cross-shaped cross section of the first spacing member (22). The method of claim 1,
The second link support body 30
A second end connector 31;
Toggle highly integrated damping damper, characterized in that it has a cross-shaped cross section and consists of a second spacing member (32) connected to the second end connector (31). The method of claim 1,
The damping element 70 is a toggle type high damping damper, characterized in that the plate-shaped high damping rubber. The method of claim 1,
The damping element 70 is an aluminum composite material in which ceramic particles are dispersed and reinforced in aluminum or an aluminum alloy, a carbon-carbon composite material, a semi-metallic friction material using metal fibers, and a metal fiber. It consists of a friction pad made of any one of low-steel friction materials that use organic / inorganic fibers and non-steel friction materials that use only organic / inorganic fibers. Toggle-type highly integrated damping damper, characterized in that. 6. The method of claim 5,
Toggle highly integrated damping damper, characterized in that the damping element 70 is composed of a plurality of friction pads protruding on the surface of the disc 71 arranged in the circumferential direction.

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